DE102009055622A1 - Weighing machine, has thermoelectric module with heating side connected with radiator that is connected with heat pipe in thermally conductive manner, where side of heat pipe is connected with cover of weighing compartment - Google Patents

Abstract

The machine (1) has a weighing compartment base (9) connected with a housing structure (2). Heat is withdrawn towards a weighing compartment (6) in a vertical direction by the base. The heat is supplied from heat sources in the vertical direction. A heating side (13) of a thermoelectric module (11) is connected with a radiator (14) in a thermally conductive manner. The radiator is arranged outside the housing structure. The radiator is connected with a heat pipe in a thermally conductive manner. A side (27) of the pipe is connected with a cover (23) of the compartment. An independent claim is also included for a method for producing a temperature coating in a vertical direction at a weighing compartment of a weighing machine.

Description

Field of the invention

The invention relates to a balance with a weighing pan on all sides surrounding a windshield, which encloses a weighing chamber, with a housing base in which a weighing pan supporting weighing system is arranged, which carries the pan carrying load bearing penetrates the housing base connected to the weighing chamber floor, and at least one a cooling and a thermoelectric module having a heating side, the cooling side of which is in thermally conductive connection with the weighing chamber floor, heat being able to be removed from the weighing chamber in a vertical direction at the bottom via the weighing chamber floor and heat from a heat source in the vertical direction.

The invention further relates to a method for producing a temperature stratification in the vertical direction in a weighing room of a balance, which is enclosed by a windshield surrounding a pan on all sides, wherein the weighing chamber in the vertical direction below via a thermoelectric module whose cooling side in thermally conductive connection with is the weighing room floor, heat is removed and in the vertical direction above heat from a heat source is supplied.

State of the art

Particularly in the case of analytical balances or precision balances with high resolution, there is a risk that the air generated in the base of the balance by electronic components, the air in the lower part of the weighing chamber is warmer than the air in the upper part. However, such air layers are unstable and undesirable.

From the DE 100 31 415 A1 is an analytical balance with a balance housing known, which consists of a base and a rear housing top. The balance has a weighing pan on all sides surrounded windshield, which encloses a weighing chamber whose bottom surface is formed by the base of the balance housing and the rear wall of the rear housing upper part of the balance housing and the other boundary surfaces are formed by at least partially movable wall elements. In order to achieve a stable air stratification in the weighing chamber, it is proposed to use thermoelectric aids with a heating and a cooling side. For example, a Peltier element is used to heat a pipe wall. While the heating end of the Peltier element is thermally conductively connected to the pipe wall, the cooling end is connected to the lower weighing chamber floor and thus cools the lower region of the weighing chamber.

Although this allows a relatively short response time of the air flow within the weighing chamber surrounded by the windscreen, but still requires an unstable air stratification with convective flow in the weighing chamber.

Furthermore, from the EP 1 396 711 A1 a balance with a device for heat dissipation known. This scale is based on the DE 100 31 415 A1 known principle to form a temperature gradient in a vertical wall of the weighing chamber, the temperature of this wall should increase from bottom to top. In this scale, the substructure is designed as a base plate, while the weighing pan supporting weighing system is arranged together with weighing electronics in a rear housing upper part. The cold side of the thermoelectric module is in contact with a supporting part of the balance, with the warm side of the thermoelectric module facing outward.

Also in this known balance the skilled person is taught to produce a temperature gradient in a vertical wall. Again, there may be an unstable air stratification with convective flow in the weighing chamber.

Finally, out of the JP 2586115 B2 a balance is known in which in a above a housing substructure arranged rear housing upper part, which adjoins a rear wall of the weighing chamber, a weighing electronics is arranged in the upper region. The heat loss of the weighing electronics should be shielded by a cooling plate connected to the cold side of a thermoelectric module. The problem with this is that the cooling plate should extend along the partition wall or side wall of the weighing chamber to below the weighing chamber floor. The arrangement of the thermoelectric module in the upper region, however, entails the risk of an unstable temperature stratification of the air located in the weighing chamber, in which the cold air is located at the top and the warm air is in a lower layer, which can lead to a convection, the it just needs to be prevented.

The known method for producing a temperature stratification in the vertical direction in a weighing room of a balance, which is enclosed by a windshield surrounding a pan on all sides, have the disadvantage that despite introduction and withdrawal of heat, an unstable air stratification with convective flow in the weighing room can arise.

task

Object of the present invention is to improve a balance, which has the weighing system and its weighing electronics in its housing base, so that no unwanted air flow arises in the closed weighing chamber.

Another object of the present invention is therefore to improve the known methods for producing a temperature stratification in the vertical direction in a weighing chamber so that no unwanted air flow is created in the closed weighing chamber.

Presentation of the invention

The object with respect to the device is achieved in conjunction with the features of the preamble of claim 1, characterized in that the warming side of the thermoelectric module is thermally conductively connected to a heat sink disposed outside the housing base and that the heat sink is thermally conductively connected to a heat pipe whose second end is connected to the ceiling of the weighing room

With the heat pipe, known to those skilled in the art as a heat pipe, a precisely einkalibrierter part of the heat of the heat sink or the warm side of the thermoelectric element can be laterally insulated from the top led to the ceiling, which is preferably formed thermally conductive. The end connected to the top in the vertical direction acts with respect to the weighing room as a "top" arranged heat source. As a heat pipe in the context of the present invention, a good heat-conducting connection is quite generally understood that is heat-insulating except for their end-side heat coupling points in the horizontal or lateral direction, ie transversely to its longitudinal extent.

For example, since the thermoelectric element formed as a Peltier element generates twice the excess heat as the heat that is pumped, the lower end of the heat pipe has a higher temperature than the weighing chamber floor. The heat pipe transports heat upwards if the Peltier element is active. This increases the upper temperature and the heat transfer process of the heat pipe is thereby less efficient. The heat transport process is in this sense tends to self-regulate.

According to a preferred embodiment of the invention, a second thermoelectric module is arranged between the heat sink and the first end of the heat pipe, wherein the cooling side of the second thermoelectric module is connected to the heat sink and the warming side of the second thermoelectric module to the first end of the heat pipe.

The second thermoelectric module can regulated heat from the hot heat sink in the heat pipe, so pump the heat transfer line. If too much heat is already introduced into the heat pipe without applying a voltage to the second thermoelectric module, the direction of the heat flow can be changed by reversing the polarity of the voltage across the second thermoelectric module. As a result, a high flexibility is given, which is particularly advantageous in terms of a shorter reaction rate.

According to a further preferred embodiment of the invention, the first end of the heat pipe is connected directly to the warming side of the thermoelectric module, while at the second end of the heat pipe, a heat sink is arranged.

From the lower end of the heat pipe behind the thermoelectric element, the heat is well insulated from the environment upwards derived. A small part of the upwardly directed heat flow is introduced via the heat conduction into the weighing chamber while the larger part is discharged to the outside via the heat sink. Due to the design of the construction (cross sections, coupling, materials), the ratio of the heat flows "inwards" / "outwards" is determined.

The arrangement of the heat sink at the upper or second end of the heat pipe eliminates the high flow of a relatively heated air to the ambient air at the rear wall of the weighing chamber. Such convectively moved air can enter heat energy in an undefined manner via the side glass walls into the weighing chamber.

According to a further preferred embodiment of the invention, a first temperature sensor is arranged in the weighing chamber in the vertical direction and a second temperature sensor in the vertical direction below, wherein a control device is provided, which is in communication with the temperature sensors and on the at least the power of the thermoelectric module in Dependent on the averaged from the values of the first and the second temperature sensor interior temperature is adjustable.

The arrangement of both the weighing system and the weighing electronics in the housing base both a heat input into the weighing chamber and a heat extraction or cooling over the weighing chamber floor is easier to control. The arrangement of the two temperature sensors in the weighing chamber allows better control of the Heat input and the cooling or heat extraction via the bottom plate. In particular, it is possible to set the total heat input to zero, which largely prevents a convective flow in the weighing room.

According to a further preferred embodiment of the invention, outside of the weighing chamber for measuring the outside temperature, a third heat sensor, which is also connected to the control device, arranged, via the control device at least the power of the thermoelectric module in dependence on the average indoor temperature and the outside temperature is adjustable ,

This makes it possible in particular to keep the average temperature in the weighing chamber on the outside temperature. This is especially advantageous when opening the draft shield, since temperature gradients between the weighing chamber and the outside space do not cause any additional air movement.

According to a further preferred embodiment of the invention, a weighing electronics arranged in the housing substructure is at least partially thermally shielded by a heat-conducting screen part, which is thermally connected to the cooling side of the thermoelectric module and to the weighing chamber floor. The warming side of the thermoelectric module is - thermally insulated from the housing base - thermally conductively connected to the arranged outside the housing base heatsink.

By the screen part is reliably avoided that heat generated by the weighing electronics uncontrollably enters from the lower housing part in the weighing chamber.

According to a preferred embodiment of the invention, the screen part is designed as a parallel to the weighing chamber floor arranged cooling plate, which is in thermal contact with the weighing chamber floor.

In this case, the cooling plate with a weighing electronics at least partially enclosing the cooling housing may be thermally conductively connected, which together form the screen part.

The cooling housing and the cooling plate are both connected to the thermoelectric element.

By enclosing the weighing electronics cooling housing on the one hand the weighing system is protected from the heat generated by the weighing electronics and on the other hand, the heat generated by the weighing electronics can not further enter the housing base, so that over the weighing room floor no heat is introduced uncontrollably into the weighing room.

The cooling housing can have a thermal insulation layer on its side facing away from the weighing electronics.

According to a further preferred embodiment of the invention, the thermoelectric module is formed as a Peltier element. In this case, a plurality of thermoelectric modules can be arranged in the housing base and connected to the screen part. By arranging a plurality of thermoelectric modules or Peltier elements, the cooling capacity of the screen part can be increased.

According to a further preferred embodiment of the invention, the weighing chamber in the vertical direction on top of the weighing chamber final ceiling made of a thermally conductive material. The blanket may also be at least partially coated with a heat-conducting layer.

As a result, on the one hand the heat coupling is facilitated and on the other hand, a uniform horizontal distribution of the injected heat is ensured.

The object with regard to the method is achieved in conjunction with the features of the preamble of claim 11 in that a second temperature value is determined in the weighing chamber in the vertical direction above with a first temperature sensor and in the vertical direction below with a second temperature sensor and a control device is supplied, and that is controlled by the control device at least the power of the thermoelectric module in dependence on the values of the first and the second temperature sensor.

According to a preferred embodiment of the invention, the heat input and the heat extraction are regulated the same size and the total heat input in the weighing room should be zero.

According to a further preferred embodiment of the invention, a third temperature value is determined outside the weighing room with a third temperature sensor for measuring the outside temperature and supplied to the control device, wherein the controller at least the power of the thermoelectric module in dependence on the from the values of the first and the second Temperature sensor averaged indoor temperature and the outside temperature determined by the third sensor is controlled.

This makes it possible in particular to regulate the average temperature in the weighing chamber according to the outside temperature, which has the advantages described above.

According to another preferred embodiment of the invention, the power control takes place with the aim of setting the first temperature value greater than the second temperature value and equating the mean temperature value averaged from the first and second temperature values to the third temperature value corresponding to the outside temperature.

Further details of the invention will become apparent from the following detailed description and the accompanying drawings, in which preferred embodiments of the invention are illustrated by way of example.

Brief description of the drawings

In the drawings show:

1 FIG. 2: shows a schematic longitudinal section of a balance with a heat pipe as the connection between a heat sink of the warm side of a thermoelectric element and a heat-conducting ceiling of the weighing chamber and a cooling plate contacting the weighing chamber floor as screen part of the weighing electronics, FIG.

2 : a schematic longitudinal section of another balance with a heat pipe as a connection between a heat sink of the thermoelectric element and a thermally conductive cover of the weighing chamber and a weighing chamber floor contacting cooling plate in conjunction with a weighing electronics enclosing cooling housing together form a screen part

3 FIG. 2: a schematic longitudinal section of a further balance with a heat pipe without representation of the weighing system with heat flow direction indicated by arrows, FIG.

4 FIG. 2: shows a schematic longitudinal section of a further balance with a heat pipe and a second thermoelectric module arranged between the heat pipe and the heat sink without showing the weighing system and FIG

5 FIG. 3: shows a schematic longitudinal section of a further balance with a heat pipe and a heat sink arranged at the upper end of the heat pipe without depiction of the weighing system.

Description of the embodiments

A balance 1 consists essentially of a housing base 2 , a weighing system 3 , a weighing electronics 4 , a weighing pan 5 and a weighing room 6 ,

A pan 5 Surrounding windscreen on all sides 7 encloses the weighing room 6 ,

In the housing substructure 2 is the weighing system 3 arranged, whose the pan 5 carrying load cell 8th the weighing room floor 9 penetrates. In the embodiment, the load receiver 8th designed as a pickup axis.

The likewise in the housing substructure 2 arranged weighing electronics 4 is opposite the weighing chamber floor 9 and the side walls of the windscreen by a screen part 10 thermally insulated.

A thermoelectric module 11 has a cold or cooling side 12 and a warm or warming side 13 on. The warming side 13 is thermally with one outside the housing base 2 arranged heat sink 14 connected. The heat sink 14 is opposite the housing base 2 by a thermal insulating material 15 thermally insulated.

According to the embodiments of the 1 to 3 is the heat sink 14 each with a first lower end in the vertical direction 25 a heat pipe 26 connected, the second upper end in the vertical direction 27 with the ceiling 23 of the weighing room 6 each via a heat coupling point 28 connected is. The warming side 13 of the thermoelectric module 11 forms over the heat sink 14 a heat source 29 for heating the upper area of the weighing room 6 ,

According to the embodiment of the 4 is between the heat sink 14 and the first end 25 of the heat pipe 26 a second thermoelectric module 31 arranged, whose the first end 25 facing warming side 34 a second heat source 33 forms.

A heat transfer to the weighing room 6 thus takes place only at the top in the vertical direction arranged Wärmeankupplungsstelle 28 ,

According to the embodiment of the 5 is the first end ( 25 ) of the heat pipe ( 26 ) directly with the warming side ( 13 ) of the thermoelectric module ( 11 ), while at the second end ( 27 ) of the heat pipe ( 26 ) a heat sink ( 32 ) is arranged.

According to the embodiment of the 1 is the screen part 10 as one approximately parallel to the weighing room floor 9 arranged cooling plate 16 formed, the thermally conductive with the weighing chamber floor 9 connected is. At her the thermoelectric module 11 facing end is the cooling plate 16 via a thermal connection piece 17 with the cooling side 12 of the thermoelectric module 11 connected.

According to the embodiment of the 2 is one of the weighing electronics 4 ' enclosing cooling housing 18 the balance 1' with the parallel to the weighing chamber floor 9 arranged cooling plate 16 ' connected, which together the screen part 10 ' form. The cooling plate 16 ' and the cooling housing 18 are at least one thermal connector 17 ' connected with each other. The cooling housing 18 points to his the weighing electronics 4 opposite side a thermal insulation layer 24 on.

The thermoelectric module 11 is formed in the embodiments as a per se known Peltier element.

In the weighing room 6 is in the vertical direction above in the embodiments of the 1 to 5 in each case a first temperature sensor 19 and in the vertical direction below, a second temperature sensor 20 arranged. Outside the weighing room 6 is a third temperature sensor for measuring the outside temperature 21 arranged. The temperature sensors 19 . 20 . 21 stand with a control device 22 in conjunction, the part of the weighing electronics 4 . 4 ' is or at least with the weighing electronics 4 . 4 ' communicates.

The thermoelectric module 11 . 31 is also with the control device 22 in connection and is regulated by this.

According to the embodiments of the 1 to 5 points the weighing room 6 in the vertical direction above a weighing room 6 final ceiling 23 made of a thermally conductive material which is in thermally conductive connection with the heat pipe.

In the 3 to 5 is the heat flow direction 30 each indicated by arrows.

To generate a temperature stratification in a vertical upward direction is the weighing room 6 vertically downwards over the weighing chamber floor 9 , the cooling plate 16 . 16 ' and the thermoelectric module 11 Heat extracted, while in the vertical direction above heat from the heat source 29 . 33 is supplied.

It is in the weighing room 6 in the vertical direction at the top with a first temperature sensor 19 a first temperature value and in the vertical direction below with a second temperature sensor 20 a second temperature value determined and a control device 22 fed.

About the control device can at least the performance of the thermoelectric module 11 depending on the values of the first temperature sensor 19 and the second temperature sensor 20 be managed.

The heat input and the heat extraction can be regulated the same size, so that the total heat input into the weighing chamber 6 Zero results.

Outside the weighing room 6 comes with the third temperature sensor 21 for measuring the outside temperature, a third temperature value is determined and the control device 22 fed. About the control device 22 will be at least the power of the thermoelectric module 11 depending on the values of the first and second temperature sensors 19 . 20 average indoor temperature and that of the third sensor 21 determined outside temperature regulated.

According to another embodiment, the power of the heat source 24 as a function of the values of the first and second temperature sensors 19 . 20 average indoor temperature and that of the third sensor 21 determined outside temperature regulated.

• – den ersten Temperaturwert größer einzustellen als den zweiten Temperaturwert und
• – den aus dem ersten und zweiten Temperaturwert gemittelten mittleren Temperaturwert dem dritten Temperaturwert, der der Außentemperatur entspricht, gleichzusetzen.

The benefit scheme is designed with the aim of

• - set the first temperature value greater than the second temperature value and
• - equating the average temperature value averaged from the first and second temperature values with the third temperature value corresponding to the outside temperature.

LIST OF REFERENCE NUMBERS

1

Libra

2

mounting support

3

weighing system

4, 4 '

Weighing Electronics

5

pan

6

Weighing space

7

windshield

8th

load sensor

9

weighing chamber base

10, 10 '

screen part

11

thermoelectric module

12

cooling side

13

warming side

14

heatsink

15

insulating material

16, 16 '

cooling plate

17, 17 '

thermal connection piece

18

cooling housing

19

first temperature sensor

20

second temperature sensor

21

third temperature sensor

22

control device

23

blanket

24

thermal insulation layer

25

first end

26

heat pipe

27

second end

28

Wärmeankupplungsstelle

29

first heat source

30

Heat flow direction

31

second thermoelectric module

32

second heat sink

33

second heat source

34

warming side

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10031415 A1 [0004, 0006]
• EP 1396711 A1 [0006]
• JP 2586115 B2 [0008]

Claims (14)

Libra ( 1 . 1' ) with a weighing pan ( 5 ) windscreen on all sides ( 7 ), which has a weighing room ( 6 ), with a housing substructure ( 2 ) in which one the weighing pan ( 5 ) carrying weighing system ( 3 ) is arranged, whose the pan ( 5 ) load bearing ( 8th ) with the housing substructure ( 2 ) associated weighing room floor ( 9 ) penetrates, and with at least one a cooling side ( 12 ) and a warming side ( 13 ) having thermoelectric module ( 11 ), whose cooling side ( 12 ) in thermally conductive connection with the weighing chamber floor ( 9 ), wherein the weighing room ( 6 ) vertically downwards over the weighing chamber floor ( 9 ) Heat extractable and in the vertical direction above heat from a heat source ( 29 . 33 ), characterized in that the warming side ( 13 ) of the thermoelectric module ( 11 ) with one outside the housing base ( 2 ) arranged heat sink ( 14 . 32 ) is thermally conductively connected and that the heat sink ( 14 . 32 ) with a heat pipe ( 26 ) is thermally conductively connected, whose second end ( 27 ) with the ceiling ( 23 ) of the weighing room ( 6 ) connected is. Scales according to claim 1, characterized in that between the heat sink ( 14 ) and the first end ( 25 ) of the heat pipe ( 26 ) a second thermoelectric module ( 31 ) and that the cooling side of the second thermoelectric module ( 31 ) with the heat sink ( 14 ) and the warming side of the second thermoelectric module ( 31 ) with the first end ( 25 ) of the heat pipe ( 26 ) connected is. Scales according to claim 1, characterized in that the first end ( 25 ) of the heat pipe ( 26 ) directly with the warming side ( 13 ) of the thermoelectric module ( 11 ), while at the second end ( 27 ) of the heat pipe ( 26 ) a heat sink ( 32 ) is arranged. Balance according to one of claims 1 to 3, characterized in that in the weighing room ( 6 ) in the vertical direction above a first temperature sensor ( 19 ) and in the vertical direction below a second temperature sensor ( 20 ) and that a control device ( 22 ) provided with the temperature sensors ( 19 . 20 ) and on the at least the performance of the thermoelectric module ( 11 ) depending on the values of the first ( 19 ) and the second temperature sensor ( 20 ) average indoor temperature is adjustable. Balance according to claim 4, characterized in that outside the weighing room ( 6 ) for measuring the outside temperature, a third heat sensor ( 21 ), which is also connected to the control 22 ), and that via the control device ( 22 ) at least the power of the thermoelectric module ( 11 ) is adjustable as a function of the average indoor temperature and the outside temperature. Balance according to one of claims 1 to 5, characterized in that a in the housing substructure ( 2 ) arranged weighing electronics ( 4 ) by a heat-conducting screen part ( 10 . 10 ' ), with the cooling side ( 12 ) of the thermoelectric module ( 11 ) and with the weighing chamber floor ( 9 ) is thermally connected, at least partially thermally shielded, and that the warming side ( 13 ) of the thermoelectric module ( 11 ) thermally from the housing base ( 2 ) isolated with the heat sink ( 14 ) is thermally conductively connected. Scales according to claim 6, characterized in that the screen part ( 10 . 10 ' ) as one parallel to the weighing chamber floor ( 9 ) arranged cooling plate ( 16 . 16 ' ) is formed, which with the weighing chamber floor ( 9 ) is in thermal contact. Scales according to claim 7, characterized in that the cooling plate ( 16 . 16 ' ) with a weighing electronics ( 4 ' ) at least partially enclosing cooling housing ( 18 ) is thermally conductively connected, which together the screen part ( 10 ' ) form. Scales according to one of claims 1 to 8, characterized in that the thermoelectric module ( 11 ) is formed as a Peltier element. Scales according to one of claims 1 to 9, characterized in that the weighing chamber ( 6 ) in the vertical direction up a weighing room ( 6 ) final ceiling ( 23 ) made of a thermally conductive material or a ceiling ( 23 ) which is at least partially coated with a thermally conductive layer. Method for producing a temperature stratification in the vertical direction in a weighing room ( 6 ) of a balance ( 1 . 1' ), which is a weighing pan ( 5 ) windscreen on all sides ( 7 ), wherein the weighing chamber ( 6 ) in a vertical direction at the bottom via a thermoelectric module ( 11 ), the cooling side in thermally conductive connection with the weighing chamber floor ( 9 ), heat is removed and in the vertical direction above heat from a heat source ( 29 . 33 ), characterized that in the weighing room ( 6 ) in the vertical direction at the top with a first temperature sensor ( 19 ) a first temperature value and in the vertical direction below with a second temperature sensor ( 20 ) determines a second temperature value and a control device ( 22 ), and that via the control device ( 22 ) at least the power of the thermoelectric module ( 11 ) depending on the values of the first ( 19 ) and the second temperature sensor ( 20 ) is regulated. A method according to claim 11, characterized in that the heat input and the heat extraction are regulated the same size and the total heat input in the weighing room ( 6 ) Returns zero. Method according to claim 11 or 12, characterized in that outside the weighing room ( 6 ) with a third temperature sensor ( 21 ) for measuring the outside temperature, a third temperature value determined and the control device ( 22 ), and that via the control device ( 22 ) at least the power of the thermoelectric module ( 11 ) depending on the values of the first ( 19 ) and the second temperature sensor ( 20 ) average indoor temperature and that of the third sensor ( 21 ) is determined outside temperature. Method according to claim 13, characterized, that the power regulation is carried out with the aim of - set the first temperature value greater than the second temperature value and - equating the average temperature value averaged from the first and second temperature values with the third temperature value corresponding to the outside temperature.

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